GE Healthcare Data File 18-1158-27 AB Cell preparation Ficoll PM7 Ficoll PM4 Ficoll PM7 and Ficoll PM4 are high molecular weight sucrose-polymers formed by copolymerization of sucrose with epichlorohydrin. The molecules are highly branched and the high content of hydroxyl groups leads to very good solubility in aqueous media. Ficoll PM7 and PM4 are supplied as spray-dried powders. Ficoll products behave as ideal neutral spheres and have been proposed as the molecules of choice for studying pore size distribution and the permeability of membranes. Ficoll PM7 and Ficoll PM4 have analogous structures, but differ in molecular weight, and are therefore appropriate for different research applications. Stability The stability of Ficoll products is chiefly determined by the glycosidic bonds in the sucrose residues. Ficoll products do not contain any ionized groups, so the structures do not react under physiological conditions. They are stable in alkaline and neutral solutions, but are rapidly hydrolyzed in solution at ph 3, especially at elevated temperature. Ficoll products can be sterilized by autoclaving at 11ºC for 3 min in neutral solutions. Strong oxidizing and reducing agents should be avoided. Shipping and storage are at ambient temperatures. Chemical and physical properties Ficoll products are provided as dry powder and are extremely hydrophilic. Solutions are best prepared by slowly stirring Ficoll powder into aqueous buffer. Gentle heating may be required for complete solubilization. Ficoll PM7 can be used at concentrations of up to 5% (w/v). Figure 2 shows the variation of viscosity of Ficoll PM7 Fig 1. Ficoll PM7 and Ficoll PM4. ηrel 5 4 3 2 1 5 1 15 2 25 3 35 4 Fig 2. Variation of viscocity with concentration for solutions of Ficoll PM7 at 2ºC. with concentration at 2ºC. Note that the viscosity of a Ficoll PM7 solution is rather less than that of a solution of dextran (M r 7 ) having the same osmotic pressure. Figure 3 shows the variation of osmolality with the concentration of Ficoll PM7. imagination at work
Osmolality, mosm/kg H 2 O 25 2 15 1 5 With Ficoll PM4 one can also obtain concentrations of up to 5% (w/v) to cover a density range with a maximum of 1.2 g/ml, without exceeding normal physiological osmolality. Figure 4 shows the comparable densities of solutions of Ficoll PM4 and sucrose as a function of concentration. Figure 5 shows the relative viscosity (η r ) at 2ºC of Ficoll PM4 solutions at different concentrations. A 3 5 1 15 Fig 3. Variation of osmolality with concentration for solutions of Ficoll PM7 at 25ºC. 1.2 Sucrose Ficoll product Osmolality, mosm/kg H 2 O 25 2 15 1 5 1.15 B 5 1 15 15 Density, g/ml 1.1 1.5 Osmolality, mosm/kg H 2 O 125 1 75 5 25 1. 1 2 3 4 5 Fig 4. Densities of Ficoll PM4 and sucrose solutions as a function of concentration. 1 2 3 4 5 Fig 6. Variation of osmolality with concentration for solutions of (A) Ficoll PM4 and (B) sucrose at 25ºC. Relative viscosity, η r 6 5 4 3 2 1 1 2 3 4 5 Fig 5. Relative viscosity (η r ) of Ficoll PM4 solutions at different concentrations. Solutions of Ficoll PM4 have much lower osmotic pressures than sucrose solutions at equivalent concentrations. Figures 6A and 6B show the variation of osmolality with concentration for Ficoll PM4 and sucrose respectively (note the considerable difference between the scales used in the two figures). The low osmolality of Ficoll products allows the formation of isotonic density gradients and preserves physiological and morphological integrity during centrifugation. You can estimate the concentration of both Ficoll PM7 and Ficoll PM4 in aqueous solutions using the anthrone reaction (1). 2 Data File 18-1158-27 AB
Ficoll PM7 Displays minimal toxicity Has favorable viscosity and osmotic properties (2) Description GE Healthcare produces a fraction of Ficoll product with an average molecular weight of 7. This material, Ficoll PM7, is specifically intended for use in perfusion media for laboratory studies on dextran-sensitive animals. Technical data Molecular weight range ~ 6 1 4 to ~ 8 1 4 Intrinsic viscosity ~ 1 ml/g Specific rotation [α] 2 + 56.5º Stokes radius ~ 5.1 nm Cl - content < 1% Applications Laboratory studies of the circulation system in animals frequently involve the use of artificial perfusion solutions of well-defined characteristics. To provide a suitable colloid osmotic pressure during the experiment, a high molecular weight polymer, frequently dextran, is added to the solution. The use of dextran for perfusion studies on rats is, however, not practically possible since infusion of dextran solutions produces anaphylactoid-like reactions in these animals (3). Ficoll PM7 has been specifically produced to make possible perfusion experiments using dextran-sensitive animals. Studies of the circulation in spontaneously hypertensive and normotensive rats using this technique have been reported by Folkow et al (4 8). A 4% (w/v) solution of Ficoll PM7 was used to provide a normal colloid osmotic pressure (7) and both whole animal (4) and isolated hindquarter preparations (5) were used. The results of these experiments have provided evidence for morphological adaptations of the resistance vessels of the systemic circuit in hypertensive rats (4,5) which may be sufficient to account for their increased flow resistance during rest. Ficoll PM7 has also proved valuable for cell isolation by unit gravity sedimentation (9). Ficoll PM4 Gives density range with a maximum of 1.2 g/ml, allowing the isolation of many types of cells and organelles (see Table 1). Has lower osmotic pressures than sucrose solutions of equal density, resulting in better preservation of the functional and morphological integrity of cells and organelles. Description In a variety of research situations inert, non ionized polymers of high molecular weight are needed. Ficoll PM4, is a synthetic neutral, highly-branched hydrophilic polymer of sucrose with an average molecular weight of 4. It has long been used in the formation of density gradients for the separation and isolation of eukaryotic cells, organelles, and bacterial cells, as a stabilizing agent and as a separation medium for the isolation of lymphocytes. It also has applications in defined culture media, nucleic acid hybridization, electrophoresis, and immunological studies. The favorable osmotic, density, and viscosity characteristics of Ficoll PM4 make it an excellent choice for many applications. Because of its high molecular weight (~ 4 ) and low content of dialyzable material, Ficoll PM4 does not normally penetrate biological membranes. Technical data Molecular weight range ~ 3 1 5 to ~ 5 1 5 Intrinsic viscosity ~ 17 ml/g Specific rotation [α] 2 + 56.5º Stokes radius ~ 1 nm Cl - content < 1% Applications Centrifugation In centrifugation methods, the density and viscosity of the medium are adjusted to allow particle sedimentation with a convenient speed. With sucrose, the high osmotic pressure, which results from the concentrations used, often damages the cells. If instead you add a high molecular weight polymer such as Ficoll product, you obtain the required density without significantly increasing the osmotic pressure. This preserves cells intact and retains their viability. Ficoll product is therefore preferred to sucrose for forming density gradients, and is primarily used in this way for the routine separation of cells (1, 11, 12) Ficoll PM4 can be used for gradient centrifugation in all types of centrifuge rotors and for separation at unit gravity. For centrifugation, both discontinuous and continuous gradients are possible. Discontinuous gradients offer two main advantages: First, the abrupt changes in Ficoll PM4 density mean that isolated cells are found in sharp bands at the interface between layers of different density. This allows for easy removal of the purified sample with a pipette. Data File 18-1158-27 AB 3
Second, cells with great differences in density can easily be isolated with as few as two density layers. This is achieved by choosing densities that will prevent one or more type of cell from entering the lower phase, banding these cell types at the interface. To estimate the densities required for a particular application, refer to Table 1. Discontinuous gradients are established as follows: 1. Using Table 1 as a guide, dissolve Ficoll PM4 in buffer or isotonic (.25 M) sucrose solution at various concentrations (generally differing by 5 to 1% w/v), which should separate the cells of interest. Most cells and organelles have a buoyant density between 1. and 1.2 g/ml in Ficoll PM4. Often, a simple two-layer gradient is sufficient. You may store these fractions in a refrigerator, but ensure that they reach room temperature before use. 2. In normal centrifuge tubes, make layers (approx. 1-cm deep) of decreasing density with the most dense solution at the bottom. 3. Keep the tubes at room temperature for a few hours to allow diffusion across the interfaces, and thereby even out the sharp borders between fractions. 4. Layer the suspension to be fractionated carefully on top. Stir the sample and upper Ficoll product layer gently with a glass rod to eliminate the interface between them before centrifugation. During centrifugation, particles collect either in or between the various Ficoll product layers, depending on the density of the layers. The cells/organelles collect at a lower density than on sucrose gradients of equivalent concentration, as Ficoll product does not penetrate cell membranes. After centrifugation, pipette off the various phases, and remove the Ficoll product from the required fraction by repeatedly diluting with buffer, and centrifuging to sediment the particles. Residual amounts of Ficoll PM4 in the sample can be estimated with the anthrone reaction (1). As an alternative to discontinuous gradients, you can easily prepare a continuous or linear density gradient of Ficoll product using a gradient mixer (13). In simple cases, you may only need one homogeneous solution (i.e., no density gradient). You can then fractionate by increasing centrifugation speed in steps. Ficoll PM4 has also been employed in zonal centrifugation studies (14). Unit gravity sedimentation through a density gradient is widely used to separate cells intolerant to centrifugation (15). Ficoll PM4 provides an economical alternative to albumin in such applications. Cells with similar densities but different size can also be efficiently separated at unit gravity (16, 17, 18). Ficoll PM7 has also been used, giving gradients of suitable osmolality yet very low viscosity (9). Cell isolation Isolation and purification of various cell types, organelles, protoplasts, cytoplasts, liposomes, minicells, bacterial cells and viruses can be accomplished on gradients of Ficoll PM4 (19, 2, 21, 22, 23). Table 1. Examples of cells, viruses and subcellular particles separated in Ficoll PM4 a. Source Density b Conditions Membranes 1.5 1 g for 16 h Chromatophores 1.7 195 g for 36 h Brain vesicles - 21 g for 15 min Hepatocyte cells 1.1 1.15 6 g for 2 h Fibroblast cells 1.5 8 g for 6 min Ehrlich ascites cells 1.7 14 g for 45 min a = Data adapted from Centrifugation: a practical approach, D. Rickwood (ed.), IRLpress (Oxford and Washington D.C.) (1984). b = Density is given as buoyant density. Chemically defined cell culture media Ficoll PM4 is used with and without serum-derived growth factors to support the growth of both primary cultures and established cell lines (24, 25). Concentration dialysis Ficoll PM4 is useful for concentrating solutions by dialysis since its high molecular weight and low content of dialyzable material prevents it crossing the dialysis membrane. Osmotic pressure draws water across the membrane into the solution of Ficoll PM4, effectively concentrating sensitive materials. Electrophoresis Continuous flow electrophoresis usually requires a stabilizer in the electrolyte. Ficoll PM4 is often employed in this capacity (26, 27). Immunological studies Ficoll PM4 can be employed as a hapten carrier, and has been conjugated to DNP, TNP, and FITC for the purpose of enhancing the primary immune response in mice. Conjugates with a range of substitution levels and minimal toxicity are easily prepared (28, 29, 3, 31). Lymphocyte isolation For routine separation of lymphocytes, we recommend Ficoll-Paque PLUS or Ficoll-Paque PREMIUM (32, 33). These are sterile, ready to use media of density 1.77 g/ml; they contain Ficoll PM4 (5.7% w/v) and sodium diatrizoate (9.% w/v). Lysis and cell particle isolation Isotonic solutions and density gradients of Ficoll products are widely used to lyse protoplasts, and extract or isolate cell particles (19, 2, 21, 22, 23). Molecular stabilization Ficoll PM4 has been used as s cryoprotective agent for unstable biomacromolecules, as well as its cryprotective properties, Ficoll PM4 has also been found to greatly contribute to the stabilization of sensitive macromolecules both in solution and during vacuum drying. 4 Data File 18-1158-27 AB
Nucleic acid hybridization A common application has been the use of Ficoll PM4 in Northern and Southern blot analysis. Ficoll PM4 (.2%), as a constituent in Denhardts solution, reduces non-specific binding of material to nitrocellulose membranes during nucleic acid hybridization (34, 35, 36). Phase partitioning Phase partitioning separates cells on the basis of surface properties. Ficoll PM4 is combined with polyethylene glycol in two-phase systems, and with dextran and polyethylene glycol in three-phase systems (37, 38). Protein quantitation An improved Ficoll PM4 density gradient method has been described for the correct determination of the protein content of crystals (39). References 1. Scott. T.A. and Melvin, E.H. Determination of dextran with anthrone. Anal. Chem., 25 1656 1661 (1953). 2. Folkow, B. et al. The hemodynamic consequences of regional hypotension in spontaneously hypertensive and normotensive rats. Acta Physio. Scand., 83 532 541(1971). 3. Morrison, J.L., Bloom, W.L., Richardson, A.P. J. Effect of dextran on the rat. Pharmacol. Exp. Therap. 11 27 28 (1951). 4. Folkow, B., Hallbäck, M., Lundgren, Y. et al. Structurally based increase of flow resistance of spontaneously hypertensive rats. Acta Physiol. Scand. 79 (197). 5. Folkow, B., Hallbäck, M., Lundgren Y. et al. Background of increased flow resistance and vascular reactivity in spontaneously hypertensive rats. Acta Physiol. Scand. 8 93 16 (197). 6. Folkow, B., Hallbäck, M., Lundgren Y. et al. Renal vascular resistance in spontaneously hypertensive rats. Acta Physiol. Scand. 83 96 15 (1971). 7. Folkow, B., Gurèvich, M., Lundgren Y. et al. The hemodynamic consequences of regional hypotension in spontaneously hypertensive and normotensive rats. Acta Physiol. Scand. 83 532 541(1971). 8. Folkow, B., Hallbäck, M., Lundgren Y. et al. The effects of immunosympathectomy on blood pressure and vascular reactivity in normal and spontaneously hypertensive rats. Acta Physiol. Scand. 84 512 523 (1972). 9. De Vries, J.E. et al. Abstracts, 4th European Immunology Meeting, Budapest, April 1978. 1. Böyum, A. A one stage procedure for isolation of granulocytes and lymphocytes from human blood. Scand. J. clin. Lab. Invest., 21 51 76 (1968). 11. Battistuzzi, G. et al. Tissue specific levels of human glucose-6-phosphate dehydrogenase correlate with methylation of specific sites at the 3 end of the gene. Proc. Natl. Acad. Sci. U.S.A., 82 1465-1469 (1985). 12. Leopardi, E. and Rosenau, W. Human t-cell mediated cytotoxicity: role of subsets and neutralization of cytotoxicity by anti-a-lymphotoxin serum. Cell. Immunol., 7 148 159 (1982). 13. Rola-Pleszczynski, M. and Churchill, W.H. Purification of human monocytes by continuous gradient sedimentation in Ficoll. J. Immunol. Methods, 2 255 262 (1978). 14. Lavrenko, P.N., Mikriukova, O.I., and Okatova, O.V., On the separation of various Ficoll gradient solutions in zonal centrifugation. Anal. Biochem. 166, 287 (1987). 15. Immunological characterization of FcR bearing and non-bearing B cells: Functional modification of immune complexes. Park, Y-H. et al. Cell. Immunol., 83 34 35 (1984). 16. Tulp, A., et al., An improved Method for the Separation of Cells by Sedimentation at Unit Gravity. Anal. Biochem. 67, 11 (1975). 17. Niskanen, E., et al. Separation by velocity sedimentation of human haemopoietic precursors forming colonies in vivo and in vitro cultures. Cell tissue Kinet. 18, 399 (1985). 18. Bont, W.S., et al, Separation of human lymphocytes and monocytes by velocity sedimentation at unit gravity. J. Immunol. Methods 29, 1 (1979). 19. Low, F-C. and Wiemken, A. Fractionation of Hevea brasiliensis latex on Ficoll density gradients. Phytochem., 23 747 75 (1984). 2. Moeller, C.H. et al. Lipid phase separations and intramembranous particle movements in the yeast tonoplast. Biochim. Biophys. Acta, 643 376 386 (1981). 21. Gennaro, R. et al. Monitoring of cytosolic free Ca 2+ in C5a -stimulated neutrophils: Loss of receptormodulated Ca 2+ stores and Ca 2+ uptake in granule-free cytoplasts. Proc. Natl. Acad. U.S.A., 81 1416 142 (1984). 22. Elliot, B.E. et al. Receptor specificity of Ia-restricted T lymphoblasts activated against trinitrobenzene sulphonate-coupled spleen cells: recognition of distinct trinitrophenyl and Ia moieties. Cell. Immunol., 121 137 (1984). 23. Sindhy, R.K. and Cohen, S.S. Subcellular localization of spermidine synthetase in the protoplasts of chinese cabbage leaves. Plant Physiol., 219 223 (1984). 24. Clark, J. In Hormonally Defined Media, Lecture Posters Eur. Conf. Serum-Free Cell Culture, Fischer, G. and Wieser, R.J. (eds), Springer (Berlin), 6, (1983). 25. Kao, K.N., Plant formation from Barley Anther cultures with Ficoll media. Z. Pflanzenphysiol Bd. 13, 437 (1981). 26. Platsoucas, C.D., and Catsimpoolas, N., Density gradient electrophoresis of mouse spleen lymphocytes: age-related differences. A critical thymus-dependent event during development in the young mouse. J, Immunol. Methods 34, 31 (198). 27. Platsoucas, C.D., Good, R.A., and Gupta, S., Separation of human lymphocyte subpopulations by density gradient electrophoresis. Cell. Immunol. 51, 238 (198). 28. McMasters, P.R.B. et al., The preparation and characterization of thymic independent antigen e-dinitrophenyl-llysine-ficoll. Immunochemistry 14, 189, (1977). 29. Inman, J.K., Thymus independent antigens: the preparation of covalent, hapten- Ficoll conjugates. J. Immunol. 114, 74 (1975). 3. IgD secreting Physiology of IgD. IV. Enhancement of antibody production if mice bearing plasmacytomas. Xue, B. et al. J. Exp. Med., 159 13-113 (1984). 31. DeHeer, D.H. and Edgington, R.S. Relationship between antibody affinity and hemolytic plaque diameter-ii. Maturation of primary immune responses to DNP and SRBC.Mol. Immunol., 17 1231 1236 (198). 32. Carlsson, R. et al. Staphylococcal Protein A (Sp A) does not induce production of interferon-g in human mononuclear blood cells. Cell. Immunol., 86 136 144 (1984). 33. Ficoll-Paque for in vitro isolation of lymphocytes (art. no. 18-1152-69). 34. Medveczky, P. et al. Classification of Herpes virus Saimiri into three groups based on extreme variation in a DNA region required for oncogenicity. J. Virol., 52 938 944 (1984). 35. Virtanen, A. et al. mrnas from human Adenovirus 2 early region 4. J. Virol., 51 822 831(1984). 36. Holland. L.E. et al. Transcriptional and genetic analyses of the herpes simplex virus type 1 genome: co-ordinates.29 to.45. J. Virol, 49 947 959 (1984). 37. Johansson, G., and Joelsson, M., J. Partition of the hydrophobic compounds between two liquid phases of similar hydrophobicity. Chromatog. 464, 49 (1989). 38. Albertsson, P.A., and Birkenmeier, G., Affintiy Separation of Proteins in Aqueous Three-Phase Systems. Anal. Biotech. 175, 154 (1988). 39. Bode. W. and Schirmer, Determination of the protein content of crystals formed by Mastigocladus laminosus c-phycocyanin, Chroomonas spec. Phytocyanin- 645 and modified human fibronogen using an improved Ficoll density gradient method. T. Biol. Chem., 366 287 295 (1985). Additional references by subject Purification/isolation of: Protein crystals Bode, W., and Schirmer, T., Determination of the Protein Content of Crystals Formed by Mastigocladus laminosus CPhycocyanin, Chroomonas spec. Phycocyanin-645 and Modified Human Fibrinogen Using an Improved Ficoll Density Gradient Method. Biol. Chem. Hoppe-Seyler 366, 287 (1985). Murine bone marrow cells Schneider, E., et al., Histamine-Producing Cell-Stimulating Activity. J. Immunol. 139, 381 (1987). Cell membranes Zafra, F., and Gimenez, D., Characterization of Glycine Uptake in Plasma Membrane Vesicles Isolated from Cultured Glioblastoma Cells. Brain Research 297, 18 (1986). Plant protoplasts Attree, S.M., and Sheffield, E., An evaluation of Ficoll density gradient centrifugation as a method for eliminating microbial contamination and purifying plant protoplasts. Plant Cell Reports 5, 288 (1986). Cytoplasts Volloch, V., Schweitzer, B., and Rits, S., Synthesis of Globin RNA in Enucleated Diofferentiating Murine Erythroleukemia Cells. J. Cell Biol. 15, 137 (1987). Endonucleobionts from host Characterization of Caedibacter Endonucleobionts from the Macronucleous of Paramecium caudatum and the Identification of a Mutant with Blocked R-Body Synthesis. Schmidt, H.J., et al., Exp. Cell Res. 174, 817 (1988). Data File 18-1158-27 AB 5
Plant cells Takeda, J., et al., Membrane Potential of Cultured Carrot Cells in Relation to the Synthesis of Anthocyanin and Embryogenesis. Plant Cell Physiol. 29, 817 (1988). Rod outer segment disk membranes Bauer, P.J., and Mavrommati, E., Permeability of Rod Outer Segment Disk Membranes as Probed by Ficoll Density Gradient Centrifugation and by Turbidimetry. Expt. Eye Res. 42, 255 (1986). Proteoliposomes from uncoupled protein aggregates Shrishailam, Y., et al., Selective killing of T lymphocytes by phototoxic liposomes. Proc. Nat. Acad. Sci. USA 84, 246 (1987). Human sperm Kaneko, S., and Moriwaki, C., Effects of Kinins and Dipeptidyl Carboxypeptidase on the Motility of Highly Washed Human Sperm. J., Pharm. Dyn. 4, 443 (1981). Vacoules of the yeast tonoplast Moeller, C.H., Mudd, J., and Thomson, W.W., Lipid Phase Separations and Intramembranous Particle Movements in the Yeast Tonoplast. Biochim. Biophys. Acta 643, 376 (1981). Pancreatic islet cells Gotoh, M., et al., Immunological Characteristics of Purified Pancreatic Islet Grafts. Transplantation 42, 387 (1986). Other applications: Virus binding studies Haywood, A.M., and Boyer, B.P., Ficoll and Dextran Enhance Adhesion of Sendai Virus to Liposomes Containing Receptor (Ganglioside GD1a). Biochemistry 25, 3925 (1986). Preparation of cytoplasts Malawista, S.E., Van Blaricom, G., and Breitenstein, M.G., Cryopreservable Neutrophil Surrogates. J. Clin. Investigation 83, 728 (1989). Generation of minicells Stieglitz, H., et al., Cloning, Sequencing, and Expression in Ficoll-Generated Minicells of an Escherichia coli Heat-Stable Enterotoxin Gene. Plasmid 2, 42 (1988). Stabilizer for rapid freezing Furuya S., Edwards, C., and Ornberg, R.L. Exocystosis of Bovine Chromaffin Granules in Ficoll Captured by Rapid Freezing. J. Electron Microsc. 38, 143 (1989). Ficoll PM7 and Ficoll PM4 are supplied as dry powders in the following pack sizes: Ordering information Product Pack size Code no. Ficoll PM7 1 g 17-31-1 5 g 17-31-5 5 kg 17-31-5 Ficoll PM4 1 g 17-3-1 5 g 17-3-5 5 kg 17-3-5 4 kg 17-3-8 Related products Ficoll-Paque PLUS 6 x 1 ml 17-144-2 6 x 5 ml 17-144-3 Ficoll-Paque PREMIUM 6 x 1 ml 17-5442-2 6 x 5 ml 17-5442-3 Percoll PLUS 25 ml 17-5445-2 1 l 17-5445-1 Percoll 25 ml 17-891-2 1 l 17-891-1 www.gehealthcare.com/cellprep GE Healthcare Bio-Sciences AB Björkgatan 3 751 84 Uppsala Sweden GE, imagination at work and GE Monogram are trademarks of General Electric Company. Ficoll-Paque, Ficoll and Percoll are trademarks of GE Healthcare companies. Percoll PLUS is protected by the following patents and equivalent patents and patent applications in other countries, which are licensed to GE Healthcare from Dendreon Corporation: US patent number 4,927,749, US patent number 4,927,75, Canadian patent number 1,338,492, Japanese patent number 2,628,59, US patent number 5,789,148, US patent number 6,15,843 and European patent number 1,47,635. A free, non-transferable license to use this product for density gradient separation purposes under the above mentioned patent rights accompanies the purchase of the product from a GE Healthcare company and its licensed distributors, but any use of Percoll PLUS or any other organosilanized colloidal silica particle-based separation media to enrich, purge or isolate cells for active immunotherapy for oncology applications shall be excluded from such license. 21 27 General Electric Company All rights reserved. First published Nov. 21 All goods and services are sold subject to the terms and conditions of sale of the company within GE Healthcare which supplies them. A copy of these terms and conditions is available on request. Contact your local GE Healthcare representative for the most current information. GE Healthcare Europe GmbH Munzinger Strasse 5, D-79111 Freiburg, Germany GE Healthcare UK Ltd Amersham Place, Little Chalfont, Buckinghamshire, HP7 9NA, UK GE Healthcare Bio-Sciences Corp 8 Centennial Avenue, P.O. 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